DE19829642A1 - Hydraulic regulating system for automatic gear - Google Patents

Abstract

A signal pressure transmitter emits a first signal.. An amplification regulator valve emits an amplification pressure regulated on the basis of the first signal pressure. A selector selects a second signal pressure and has a shut-off ball. A regulator to which the second signal pressure is supplied regulates the transmitter pressure Two adjustment mechanisms adjust the amplification regulator valve and signal pressure transmitter.

Description

The present invention relates to a hydraulic Control system for an automatic transmission. In particular relates they rely on a hydraulic control system for one Automatic transmission, the hydraulic control system one Output pressure with a different gain factor controls that relates to a signal pressure.

Generally there is a linear solenoid valve in one conventional hydraulic control system for a Automatic transmission from a signal pressure, the signal pressure is entered into a primary control valve and the primary Control valve regulates a line pressure to one Output pressure, which is suitably on the signal pressure based. Then many tax types are based on the outlet pressure. A rate of change of Output pressure from the primary control valve, which relates to a Change in signal pressure output from the linear Solenoid valve is using a Gain made the gain from now on is called. The gain is set so that the Line pressure is adjusted to the outlet pressure required for the hydraulic control within the range of the Signal pressure is required, which is from the linear magnet or Solenoid valves is output. That is, the reinforcement is set so that the range of change of the Outlet pressure within the change range of the Signal pressure is reached.

For example, in a continuously variable Gearbox that uses a stepless shift by changing one  Pulley ratio between two pulleys that tied with a strap, performs an unusual high outlet pressure required. That is, with one that will be continuously variable transmission Pulley ratio by increasing and decreasing one Tension on the belt through a fixed drive pulley and changed a movable drive pulley, each Has pulley. The tension on the belt must decrease change over a wide range. Therefore it is necessary that the output pressure from the primary control valve to Achieving tension on the belt over the wide range changed over a wide range. As a way to achieve of the wide range of changes in the outlet pressure can Area of the signal pressure can be made large. In this case the linear solenoid valve must be large to accommodate the wide one To achieve change range for the signal printing. Therefore becomes a great space for positioning the great linear Solenoid valve needed and the cost increases.

As another way to achieve the wide range of change the outlet pressure taking into account the above Disadvantages described, it is possible to To make the amplification factor large. In this case, if the Gain is large, is the change in the Outlet pressure, which is related to the change in signal pressure relates, great. Subsequently, however, the spread of the Output pressure large due to the vibration in the signal pressure. That is why it is difficult to have high accuracy control for to reach the outlet pressure. That is, in case where the change range of the signal pressure is stable, the Change range of the outlet pressure large and the high Outlet pressure is reached when the gain factor is like this is set that it is large, but the one highly accurate It is difficult to control the outlet pressure. If the Gain is set to be small  high-precision control of the outlet pressure reached, but the range of change of the outlet pressure becomes small and the necessary high outlet pressure will not reached.

In fact, the one mounted in a vehicle needs protruding continuously variable transmission described the big one Output pressure, for example at the vehicle start, because that Pulley ratio must be changed greatly. And, for example during a constant driving speed the continuously variable transmission needs a small one Output pressure, for example for the purpose of minimizing the Fuel economy and maintaining one high-precision control of the outlet pressure. That is, in the continuously variable transmission is a small one Gain factor suitable if the continuously variable Gearbox needs a low output. If that continuously variable transmission high output a large gain factor is suitable.

The linear solenoid valves and control valves have variations, which, for example, by the manufacturing accuracy and the Mounting accuracy of the valve body and the coil body are caused, and by the spring load of the spring, which the Load the bobbin in each assembly unit. Therefore have the signal pressure from the linear solenoid valves and the Control pressures from the control valves spread with respect to the same current value in each hydraulic circuit. This means, the control pressure as output, based on the current value as Entrance, has a degree of dispersion.

To reduce the spread in each hydraulic circuit an adjustment mechanism in the linear solenoid valve arranged. For example, a Adjusting screw to increase or decrease the spring load of the  Spring that loads the bobbin. In this The spring load can be adjusted by adjusting the screw in each case Hydraulic circuit can be increased and decreased, and then the signal pressure and the control pressure are related to the Signal pressure regulated. This will set the appropriate control pressure reached.

Fig. 12 shows an example for regulating the control pressure from the prior art. FIG. 12 shows a linear change in the control pressure P _L , the variation with respect to the current values I of the linear solenoid valves being determined in various hydraulic circuits. In Fig. 12, the solid line A shows a target value, the upper side of the alternating long and twice short dashed line a ₁ shows a maximum value of the scatter before the adjustment, a lower side of the alternately long and twice short dashed line a ₂ shows a minimum value the scatter before the adjustment, an upper side of the alternately long and short dashed line b ₁ shows a maximum value of the scatter after the adjustment and a lower side of the long and short dashed line b ₂ shows a minimum value of the scatter after the adjustment.

The control pressure P _L is set as follows.

In the prior art, a set point (base point) is set on a low pressure side of the control pressure P _L and the control pressure P _L is controlled so that the control pressure P _{L is} a predetermined control pressure P _A. In fact, the current value of the linear solenoid is maintained at a predetermined value. Then, while observing the control pressure output from the control valve, a thrust amount of the adjustment screw is adjusted and the adjustment is ended when the control pressure P _{L reaches} the predetermined control pressure P _A.

When adjusting from the upper side of the alternately long and twice short dashed line a ₁ , the load amount of the adjusting screw increases and the left end of the line a ₁ is set to the predetermined control pressure P _A. When adjusting from the lower side of the alternately long and twice short dashed line a ₂ , the load amount of the adjusting screw is reduced and the left end of the line a ₂ is set to the predetermined control pressure P _A. With this method, lines a ₁ and a _{2 are} offset in parallel and shifted to lines b ₁ , b ₂ .

By performing the setting for each hydraulic circuit, the predetermined control pressure P _A for the predetermined current value of the linear solenoid valve is reached in each hydraulic circuit. That is, the predetermined control pressure is set to correspond to the predetermined current value.

However, in the prior art, the spread after adjustment is large when the control pressure P _{L is} high because the set point is set for the low pressure side of the control pressure P _L. Therefore, the hydraulic pressure that can be output is too large compared to the target value A shown in FIG. 12. As a result, it is necessary to take into account the strength and reliability of the hydraulic circuit when such a high pressure results.

Conversely, when the set point is set on the high pressure side of the control pressure P _L , the dispersion at the set point on the high pressure side is reduced, but the dispersion on the low pressure side is increased. It is therefore necessary to set the lowest control pressure so high that the control pressure is sufficient for the large spread on the low pressure side.

When the set point of the control pressure P _{L is set} on the low pressure side, the spread on the high pressure side is increased, and when the set point of the control pressure P _L on the high pressure side is set, the spread on the low pressure side is increased. That is, the spread of the control pressure P _L is increased on a side far from the set point because the setting by the adjusting screw does not change the loop of the lines in Fig. 12, but just displaces them in parallel.

It is therefore an object of the present invention to provide a hydraulic control system for an automatic transmission too create that both high tax accuracy for one Outlet pressure as well as a high outlet pressure Changing a gain factor, the so-called Gain factor, which is based on a change in the Signal pressure relates, achieved.

An aim of the invention is to spread the Outlet pressure, which is a control pressure, by setting to reduce two setting points.

In order to solve the above-mentioned problem, a hydraulic control system for an automatic transmission Signal pressure output device on a first Signal pressure outputs one Gain changing device, the first Receives signal pressure from the signal pressure output device and a second signal print based on the first signal print outputs, and a control device, the second Signal pressure from the gain changing device receives and regulates an outlet pressure which is on the second  Signal printing based. The Gain changing device changes the Gain factor that determines the rate of change of the Initial pressure regarding the change in the first Represents signal pressure to a low gain and a high gain factor within one Change range of the first signal pressure. The Gain changing device has Gain control valve on the one Output boost pressure based on the first Signal pressure is regulated, and a selector that selects the second signal pressure from the first signal pressure and the boost pressure based on their strength.

The selection device has a shut-off ball valve that the higher pressure from the first signal pressure and the Selects boost pressure as the second signal pressure and the outputs second signal pressure to the control device.

The first signal print is the second signal print in the Control device entered and the gain factor changed to the lower gain when the first Signal pressure from the signal pressure output device lower is as a predetermined value, and the Gain pressure that is higher than the first signal pressure is the second signal pressure to the regulating device entered and the gain factor is set to the high Gain changes when the first signal pressure from of the signal pressure output device higher than the predetermined one Is worth.

The boost control valve regulates the outlet pressure is regulated by the control device on the Gain pressure. The gain control valve regulates the gain pressure from low to high when  the first signal pressure from low to high changed.

The hydraulic control system for an automatic transmission has a first adjustment mechanism that the first Signal printing by adjusting the signal printing output device regulates, and a second adjustment mechanism that the Gain pressure by adjusting the Gain control valve regulates. The first Adjustment mechanism regulates the first signal pressure on a base point on a low pressure side of the outlet pressure based on the control device, and the second Adjustment mechanism controls the gain pressure based on a base point on a high pressure side of the Output pressure from the control device.

The setting for the first signal print by the first Adjustment mechanism is carried out earlier than that Setting for the gain pressure by the second Adjustment mechanism.

Another way to accomplish the above tasks has a hydraulic control system for an automatic transmission a signal printing output device having a first Signal pressure outputs one Gain changing device, the first Receives signal pressure from the signal pressure output device and outputs a second signal pressure that is on the first Signal pressure based, and a control device that the second signal pressure from the Gain changer receives and one Output pressure controls based on the second signal pressure. The gain changing device changes one Gain factor, which is the rate of change of the outlet pressure in relation to the change in the first signal pressure, to one  low gain and high Gain factor within a change range of the first signal pressure. The Gain changing device has Boost control valve on that a boost pressure outputs, which is regulated based on the first signal pressure becomes. The gain changing device gives that first signal pressure as the second signal pressure to the Control device off when the first signal pressure is lower than is a predetermined value, and the Gain changing device gives both the first Signal pressure as well as the boost pressure as the second Signal pressure to the control device when the first Signal pressure is higher than or equal to the predetermined value.

The boost control valve regulates the outlet pressure, the is regulated by the control device on the Boost pressure. The gain control valve regulates the Boost pressure from low to high when the first signal pressure changes from a low to a high changed.

The hydraulic control system for an automatic transmission has a first adjustment mechanism that the first Signal printing by adjusting the signal printing output device regulates, and a second adjustment mechanism that the Boost pressure by adjusting the Boost control valve regulates. The first Adjustment mechanism controls the first signal pressure based on a base point on a low pressure side of the Output pressure from the control device, and the second Adjustment mechanism regulates the boost pressure based on a base point on a high pressure side of the outlet pressure from the control device. The setting for the first Signal pressure through the first adjustment mechanism gets earlier  performed as the setting for the boost pressure through the second adjustment mechanism.

According to the invention, the gain factor changes (Amplification) of the outlet pressure related to the first Signal pressure by the gain changing device to a low gain factor. Therefore the Change in output pressure related to the first signal pressure reduced. As a result, the accuracy of the Output pressure related to the first signal pressure increased. Furthermore, the gain factor (gain) of the Output pressure based on the first signal pressure by the Gain change device to the high Gain changed. Therefore the change of the Output pressure related to the first signal pressure increased. As a result the high outlet pressure is reached. In this Case is a print of the first signal print and the Boost pressure selected based on their height and the selected pressure is considered the second signal pressure by the Gain control valve and the selector to the Control device issued. Then the differ Gain that is achieved when the first signal pressure is on the control device is entered, and the gain that is reached when the boost pressure to the Control device is entered. Therefore two different reinforcements, that is the low one Get reinforcement and the high gain.

The higher pressure is easily reduced by the shut-off ball valve selected the first signal pressure and the boost pressure. Therefore, the design for selection is simplified.

In the event that the first signal pressure increases, the selected the first signal pressure as the second signal pressure and on the control device is output and the gain is on  the low gain changed when the first signal pressure is lower than the predetermined value, and the Boost pressure that is higher than the first signal pressure is selected as the second signal print and sent to the Control device issued, the gain to high Gain is changed when the first signal pressure is higher than the predetermined value. That is, in the case where the first signal pressure increases, the gain becomes automatically from low gain to high Gain changed based on the predetermined value. The boost pressure is stabilized because of the Boost pressure from the outlet pressure generated by the Regulating device is regulated, is regulated.

When the first signal pressure increases, the Boost pressure too. The first signal pressure is based on the base point on the low pressure side of the low Output pressure regulated by the control device. Of the Boost pressure is based on the base point on the High pressure side of the high outlet pressure from the Regulating device regulated. That is, the outlet pressure of the control device is based on the two base points on both the low pressure side and the high pressure side the first adjustment mechanism and the second Adjustment mechanism regulated. Therefore the spread of the Output pressure from the control device on the Low pressure side and the high pressure side reduced and the Output pressure accuracy increases.

The gain control valve is controlled by the Signal pressure output device regulated. Therefore the Boost pressure influenced by the first signal pressure. As a result will reduce the accuracy of the scheme if the gain control valve through the second Adjustment mechanism is set before the  Signal printing output device by the first Adjustment mechanism is set. To the problem encounter, the signal pressure output device by the first adjustment mechanism set before that Boost control valve through the second Adjustment mechanism is set. Therefore, the Accuracy of the scheme too, because the first signal pressure is not is influenced by the boost pressure.

According to another construction of the invention, the Gain factor (gain) related to the outlet pressure at the first signal print by the Gain changing device to a low one Gain changed. Therefore the change of the Output pressure related to the first signal pressure reduced. As a result, the accuracy of the outlet pressure decreases based on the first signal print. Furthermore, the Gain factor (gain) related to the outlet pressure at the first signal print by the Gain change device to the high Gain changed. Therefore, the change of Output pressure related to the first signal pressure. As a The result is the high outlet pressure. In this case the first signal print is sent to the second signal print Control device entered when the first signal pressure is lower than the predetermined value and both the first signal pressure as well as the boost pressure as second signal pressure input to the control device if the first signal pressure is higher than the predetermined value. Then the gain that is achieved differs when the first signal pressure is input to the control device and the gain that is achieved when the first Pressure and the boost pressure to the control device can be entered. That is why two are different Receive reinforcements, that is the low gain and  the high gain. Furthermore, the gain becomes uniform changed because the first signal printing always to the Control device is entered.

The boost pressure is stabilized because of the Booster pressure is regulated by the outlet pressure that is regulated by the control device. If the first Signal pressure increases, the boost pressure increases.

The first signal pressure is based on the base point the low pressure side of the low outlet pressure from the Regulating device regulated. The boost pressure will based on the base point on the high pressure side of the high Output pressure regulated by the control device. This means, the output pressure from the control device is in each case based on the two base points on the low pressure side and the high pressure side through the first adjustment mechanism and regulated the second adjustment mechanism. Therefore the Scattering of the output pressure from the control device at the Low pressure side and the high pressure side reduced and the Output pressure accuracy increases.

The gain control valve is controlled by the Signal pressure output device regulated. Therefore the Boost pressure influenced by the first signal pressure. As a result, the control accuracy is reduced if that Boost control valve through the second Adjustment mechanism is set before the Signal printing output device by the first Adjustment mechanism was set. To solve this problem encounter, the signal pressure output device by the first adjustment mechanism set before that Boost control valve through the second Adjustment mechanism is set. Therefore, the  Control accuracy too, because the first signal pressure is not is influenced by the boost pressure.

The invention will now be read in conjunction with the following Described drawings in which the same features same reference numerals.

Fig. 1 is a schematic diagram of a continuously variable transmission of the invention.

Fig. 2 is a figure showing a hydraulic circuit which is a basis of the invention.

Fig. 3 is an enlargement of a portion of Fig. 2 for explaining the gain of a line pressure.

Fig. 4 is a figure showing a hydraulic circuit of the invention.

FIG. 5 is an enlargement of a portion of FIG. 4, showing the gain changing device of a first embodiment.

Fig. 6 is a modified enlargement of a portion of Fig. 4, showing a gain changing device of a second embodiment.

Fig. 7 is a figure showing the relationship between a first signal pressure and a line pressure in the first embodiment.

Fig. 8 is a figure showing the relationship between a first signal pressure and a line pressure in the second embodiment.

Fig. 9 is a figure showing the hydraulic circuit in the first embodiment which has an adjustment mechanism.

Fig. 10 is a figure showing a relationship between a current value and a regulating pressure in the first embodiment.

Fig. 11 is a figure showing the hydraulic circuit in the second embodiment which has an adjustment mechanism.

Fig. 12 is a figure showing a relationship between a current value and a control pressure in the prior art.

The invention is based on a detailed description of preferred embodiments with reference to the attached drawings much more understandable.

In this description words like upper, lower, upper or continuously below in the conveying or transport directions used. These words refer to the figures and do not represent an absolute direction. Terms like first Direction, opposite direction and second direction could also be used, but they would add Arrows to the figures and additional explanations need. Thus, for simplification, words related to the visual representation used and are not intended to be limiting be meant.

The first embodiment of the invention is described in the following order:

• (1) A construction of a continuously variable Gearbox operated by a hydraulic control system for a Automatic transmission is supplied.  
• (2) A construction of a hydraulic circuit that is a base forms the invention.
• (3) Functions of the continuously variable transmission and hydraulic circuit.
• (4) regulating a line pressure P _L.
• (5) A construction of the hydraulic control system for one Automatic transmission.
• (6) A function of the hydraulic control system.
• (7) The setting of valves in the hydraulic Control system.

The construction of a continuously variable transmission supplied with a hydraulic control system for an automatic transmission of the invention will be described with reference to FIG. 1. The figure shows the outline of a structure of a continuously variable transmission for a vehicle, which is supplied with a hydraulic control system for an automatic transmission.

As shown in Fig. 1, the continuously variable transmission 1 has a CVT 2 (which is a belt type continuous variable transmission mechanism), a forward / reverse mode selector 3 , a torque converter 6 equipped with a lockup clutch 5 , a counter shaft 7 and a differential device 9 . These devices are covered by a split housing.

The torque converter 6 has a pump impeller 11 , which is connected to an engine output shaft 10 via a front cover 17 , a turbine rotor 13 , which is connected to an input shaft 12 via a one-way clutch 15 , and a stator 16 , which is supported on the transmission housing. A lockup clutch 5 is interposed between the input shaft 12 and the front cover 17 . A damper spring 20 is inserted between the locking clutch plate and the input shaft 12 . An oil pump 21 is connected to the pump impeller 11 and is driven by this.

The CVT 2 has a primary pulley 26 , a secondary pulley 31, and a metal belt 32 that is wrapped around the pulleys 26 , 31 . The primary pulley 26 has a fixed drive pulley 23 , which is fastened to a primary shaft 22 , and a movable drive pulley 25 , which is axially slidably mounted on the primary shaft 22 . The secondary pulley 31 has a fixed drive pulley 29 which is fixed to a secondary shaft 27 and a movable drive pulley 30 which is axially slidably supported on the secondary shaft 27 .

A hydraulic actuation device 33 , which has a double piston, is arranged behind the movable drive disk 25 on the primary side. A hydraulic actuator 35 , which has a single piston, is arranged behind the movable drive pulley 30 on the secondary side. The hydraulic actuation device 33 on the primary side has a cylinder component 36 and a reaction support component 37 , which is fastened to the primary shaft 22 and a piston component 40 and a cylindrical component 39 , which is fixed to the movable drive disk 25 . A first hydraulic chamber 41 is formed by the cylindrical component 39 , the reaction support component 37 , the primary shaft 22 and the rear of the movable drive disk 25 . A second hydraulic chamber 42 is formed by the cylinder component 36 , the piston component 40 and the reaction support component 37 . The first hydraulic chamber 41 and the second hydraulic chamber 42 are made continuous through a through hole 37 a. As a result of the combination of the same hydraulic pressures in the hydraulic chambers 41 , 42 , a force is generated in the axial direction roughly twice that of a secondary side hydraulic actuator 35 . The secondary side hydraulic actuator 35 has a reaction support member 43 that is attached to the secondary shaft 27 and a cylindrical member 45 that is attached to the rear of the movable drive pulley 30 . A single hydraulic chamber 46 is formed by these components and the secondary shaft 27 . A spring 47 under tension is arranged between the movable drive disk 30 and the reaction support component 43 and compressed.

The forward / reverse mode selector 3 has a double pinion planetary gear 50 , a reverse brake B1, and a direct clutch C1. In the double-pinion gear 50 , a sun gear S is connected to the input shaft 12 , a carrier CR, which carries a first pinion P1 and a second pinion P2, is connected to a drive disk 23 fastened on the primary side, a ring gear R is connected to the reversing brake B1 and the Direct clutch C1 is arranged between the carrier CR and the ring gear R.

A large gear 51 and a small gear 52 are attached to the counter shaft 7 . The large gear 51 rolls with a gear 53 which is attached to the second shaft 27 . The small gearwheel rolls with a gearwheel 55 of the differential device 9 . In the differential device 9 , the rotation from a differential gear 56 supported by a differential case 66 containing the gear 55 is transmitted to the left and right axles 60 , 61 via left and right side gears 57 , 59 .

A plurality of irregular sections 23 a are formed with an equal space on the outer section of the drive pulley 23 fastened on the primary side by toothing. An electromagnetic pickup 62 is attached to a position opposite the irregular portions 23 a of a housing. Furthermore, many irregular sections 29 a are formed with an equal space on the outer section of the drive pulley 29 fastened on the secondary side by toothing. An electromagnetic pickup 63 is attached to a position opposite the irregular portions 29 a of the housing. The electromagnetic transducers 62 , 63 are arranged so that the detection surfaces of the electromagnetic transducers 62 , 63 are close to the irregular sections 23 a, 29 a. The electromagnetic pickup 62 forms a primary (input) speed sensor for detecting the irregular sections 23 a. The electromagnetic pickup 63 forms a secondary (output) speed sensor (vehicle speed sensor) for detecting the irregular sections 29 a. An electromagnetic pickup 65 is arranged close to the front cover 17 . The electromagnetic pickup 65 forms an engine speed sensor.

An input torque is calculated as follows. An engine torque is obtained from a table based on a throttle opening and an engine speed. Such tables are known from the prior art. A speed ratio is calculated based on an input speed and an output speed of the torque converter 6 . A torque ratio is obtained from a table based on the speed ratio.

Such tables are known from the prior art. The Input torque is obtained by multiplying the Torque ratio and engine torque calculated.

The construction of the hydraulic circuit of the continuously variable transmission 1 will be described with reference to FIG. 2. In the invention, as will be discussed below, a gain changing device, such as a gain control valve 110 in FIG. 4, is added to the hydraulic circuit shown in FIG. 2.

In Fig. 2, there is an oil pump 21 , an oil pump control valve 70 and an oil pump solenoid valve S2 for the oil pump control valve. Furthermore, a primary control valve 72 is shown, a secondary control valve 73 , a linear solenoid valve SLT for a line pressure for regulating the line pressure, a linear blocking solenoid valve SLU for blocking regulation, a linear ratio solenoid valve SLR for a ratio regulation and a modulation valve 76 for regulating the solenoid or solenoid valves.

A manual valve 77 is manually operated to switch a modulated pressure modulated by a clutch modulation valve 79 from an opening 1 to an opening 2 or an opening 3 , as shown in the table in FIG. 2 or 4. In Fig. 2 is a C1-regulating valve 80 is further shown, a neutral-transfer valve 81, a reversal prevention valve 82 and a solenoid valve S1 for controlling the forward / reverse operation. Furthermore, a hydraulic servo device C1 for the direct clutch C1 is shown, a hydraulic servo device B1 for the reverse brake B1, a memory 90 for the hydraulic servo device B1, and a memory 91 for the hydraulic servo device C1. A ratio control valve 92, a hydraulic primary side actuation device 33 and a hydraulic secondary side actuation device 35 are also shown there. A lock control valve 95 , a lock transfer valve 96 and a solenoid valve S3 for changing the lock state are also shown. In Fig. 2 EX shows a drainage opening. Furthermore, a bypass control valve 97 , a secondary control pressure modulation valve 99 and a cooler 100 are shown.

The operation of the continuously variable transmission 1 and the hydraulic circuit will now be described. By operating the oil pump 21 based on the engine rotation, a predetermined pressure is obtained. The predetermined pressure is adjusted by the primary control valve 72 to a line pressure P _L based on the line pressure linear solenoid valve SLT, which is controlled by a signal calculated by a control unit based on the pulley ratio and the input torque. The line pressure P _L is regulated by the secondary control valve 73 to a secondary pressure P _S , which will be explained below. When a high line pressure is not required, for example when a vehicle is stopped, the pump solenoid valve S2 is controlled based on a signal from the control unit so that the oil pump control valve 70 is moved to a right half-side position as shown in Fig. 2 and the predetermined one Pressure from the oil pump 21 is circulated.

When the manual valve 77 is in the D (drive) range or L (low) range, the hydraulic pressure is applied from the port 1 through the port 2 to the hydraulic servo device C1 for the direct clutch C1 and the direct clutch C1 enters Intervention. In this state, the rotation of the motor output shaft 10 via the torque converter 6, the input shaft 12 and the planetary gear 50 is, simply as a result of engagement of the clutch C1 in a direct connection state is transmitted to the primary pulley 26th The rotation is transmitted to the secondary shaft 27 via the CVT2 when the CVT2 is appropriately modified, and is then transmitted to the left and right axles 60 , 61 via the countershaft 7 and the differential device 9 .

When the manual valve 77 is moved to the R (reverse) range, the hydraulic pressure is applied from the port 1 through the port 3 to the hydraulic servo B1 for the brake B1. In this state, a ring gear R of the planetary gear 50 is engaged while the rotation of a sun gear S is converted from the input shaft 12 to a reverse rotation by the carrier CR, and the reverse rotation is transmitted to the primary pulley 26 .

In the CVT2, the line pressure P _{L is applied} from the primary control valve 72 to the hydraulic actuator 35 of the secondary pulley 31 so that a belt gripping force is applied based on the input torque and the shift ratio. The ratio linear solenoid valve SLR is controlled for ratio control based on the shift signal from the control unit, and the ratio control valve 92 is controlled by the signal pressure from the ratio linear solenoid valve SLR. The regulated pressure from the output port of the ratio control valve 92 is applied to the primary pulley 26 on the hydraulic actuator 33 having the double piston. Then the transmission ratio of the CVT2 is regulated appropriately.

The torque of the engine output shaft 10 is transmitted to the input shaft 12 via the torque converter 6 . Especially when the drive of a vehicle is started, the torque is converted by the torque converter 6 to be high and is transmitted to the input shaft 12 . Then a vehicle drives off evenly. The torque converter 6 has the locking clutch 5 . When the high speed driving condition is stable, the lockup clutch 5 is engaged, then the engine output shaft 10 is directly connected to the input shaft 12 , so that a power loss based on the oil in the torque converter is reduced.

The control of the line pressure P _L will be described with reference to FIG. 3. A spring 72 b is arranged in a first end chamber 1 of the primary control valve 72 and compressed. A control pressure outlet from the outlet opening m of the line pressure linear solenoid valve SLT is input into the first end chamber 1 via an opening 101 . The line pressure P _L is input via an opening 102 into a second end chamber n of the primary control valve 72 . Therefore, a bobbin 72 a is actuated through the control pressure input into the first end chamber 1 and the feedback pressure input into the second end chamber n. Subsequently, a hydraulic pressure applied by the oil pump 21 to an opening o of the primary control valve 72 is controlled by connecting the opening o to a drainage opening EX and a second opening q at a predetermined rate. Then the line pressure P _{L is} calculated based on the input torque and the transmission ratio of the GVT2 is applied to an oil path h.

A spring 73 b is arranged in a first end chamber r of the secondary control valve 73 and compressed. A control pressure output from the output opening s of the secondary control pressure modulation valve 99 is input into the first end chamber R via an opening 103 . The secondary pressure P _S is input via an opening 105 into a second end chamber t of the secondary control valve 73 . Therefore, a bobbin 73 a is operated through the control pressure input into the first end chamber R and the feedback pressure input into the second end chamber t. Subsequently, a hydraulic pressure applied from the opening q of the primary control valve 72 to an opening u of the secondary control valve 73 is controlled by communicating the opening u with a drainage port EX and a lubricating oil port v at a predetermined rate. The secondary pressure P _S is then applied to an oil path p based on the control pressure from the outlet opening s of the secondary control pressure modulation valve 99 . A lubricating pressure is applied from the lubricating oil opening v of the secondary control valve 73 to an lubricating device 107 via an opening 109 .

A spring 99 b is arranged in a first end chamber w of the secondary regulating pressure modulation valve 99 and compressed. The control pressure output from the outlet opening s of the secondary control pressure modulation valve 99 is input via an opening 106 to a second end chamber x. The secondary regulating pressure modulation valve 99 has the outlet openings, a drainage opening EX and an inlet opening y, to which the control pressure is applied by the line pressure linear solenoid valve SLT for regulating the line pressure P _L via an opening 104 . The outlet opening s is connected to the inlet opening y and the drainage opening EX at a predetermined rate. A V-shaped notch y 'is formed in the entrance opening y.

A spool 99 a is operated based on the control pressure as a feedback pressure input into the second end chamber x and a biasing force of the spring 99 b in the first end chamber w. If the control pressure from the line pressure linear solenoid valve SLT is lower than a predetermined pressure, the coil body 99 a remains in the right half-side position of FIG. 5, because the biasing force of the spring 99 b is higher than the feedback pressure input into the second end chamber x, and the control pressure input is then input from the outlet opening s to the inlet opening y. If the control pressure from the line pressure linear solenoid valve SLT is higher than the predetermined pressure, the spool 99 a is operated with the feedback pressure input to the second end chamber x and the biasing force of the spring 99 b in the first end chamber w. Therefore, the control pressure from the outlet port s remains at a set value at the time when the control pressure from the line pressure linear solenoid valve SLT has increased.

Therefore, the line pressure linear solenoid valve SLT for regulating the line pressure P _L regulates a modulation pressure P _M based on the control signal output from the control unit based on the input torque and the transmission ratio of the GVT2, and gives the regulated pressure as the control pressure from the output port m out. Subsequently, the primary control valve 72 outputs the line pressure P _L in relation to the input torque between a U / D (under drive) state and an O / D (over drive) state of the GVT2 based on the control pressure that is controlled which is applied to the first end chamber 1 of the primary control valve 72 .

When the control pressure from the line pressure linear solenoid valve SLT is lower than the predetermined pressure, the secondary control pressure modulation valve 99 outputs the control pressure from the output port s which is not controlled. Then the secondary control valve 73 outputs the secondary pressure P _S in relation to the input torque between the U / D (low drive (under drive)) state and the O / D (excessive drive (over drive)) state of the CVT2 based on the control pressure, which is not regulated, which is applied from the first end chamber r of the secondary regulating valve 73 . The secondary pressure P _S in the O / D state is set to a required pressure that is required for the torque converter 6 . The secondary pressure P _S is therefore sufficient in the U / D state.

The control pressure from the outlet ports of the secondary control pressure modulation valve 99 is maintained at the regulated value when the control pressure from the line pressure linear solenoid valve SLT is higher than the predetermined pressure. Therefore, the line pressure P _{L increases} in proportion to the control pressure from the line pressure linear solenoid valve SLT, but the secondary pressure P _S is limited to the regulated value based on the regulated control pressure from the outlet port s. The upper limit of the secondary pressure P _S is lower than a limit value of the torque converter 6 and is approximately equal to a highest pressure required. The limit pressure is a minimum pressure at which the torque converter 6 becomes inoperative. The highest pressure required is a maximum pressure based on the maximum input torque.

The hydraulic control system for an automatic transmission has a signal pressure output device, a gain change device and a control device, and causes changes between a low gain and a high gain. As shown in FIGS. 4 and 5, the gain change device is positioned between the line pressure linear solenoid valve SLT as the signal pressure output device and the primary control valve 72 as the control device, as compared to the hydraulic circuit as shown in FIGS. 2 and 3 . In Fig. 4, the elements having the same structure and functions as the elements in Fig. 2 have the same reference numerals and letters as shown in Fig. 2. Some elements that do not relate to the invention of FIG. 4 do not correspond to the elements in FIG. 2. For example, the cut-off valve 95 of FIG. 2 is omitted in FIG. 4.

The line pressure linear solenoid valve SLT as the signal pressure output device is the same valve mentioned with reference to FIGS. 2 and 3. That is, the line pressure linear solenoid valve SLT regulates the modulation pressure P _M from the solenoid modulation valve 79 based on the control signal based on the input torque and the shift ratio from the CVT2 from the control unit, and outputs the regulated pressure as a first signal pressure P ₁₀ the exit opening m.

In Figs. 4 and 5, which show the first embodiment, the gain changing means to a gain control valve 110 and a Absperrkugelventil 111 as a selection device. As shown in FIG. 5, the boost control valve 110 has a hydraulic chamber a to which the first signal pressure P ₁₀ output from the line pressure linear solenoid valve SLT is input, an input port c to which the line pressure P _L output from the primary control valve 72 is inputted, and an output port b, from which a boost pressure P _G , which is regulated by the line pressure P _L based on the first signal pressure P ₁₀ , is output. The gain control valve 110 further includes a bobbin 110 a, comprising the lands _{L1, L2.} The coil former 110 a is biased upwards by a spring 110 b.

The shut-off ball valve 111 has two inputs 111 a, 111 b and one output 111 c. The input 111 a is supplied with the input of the first signal pressure P ₁₀ from the line pressure linear solenoid valve SLT. The input 111 b is supplied with the input of the boost pressure P _G from the boost control valve 110 . The higher pressure is selected from the first signal pressure P ₁₀ and the boost pressure P _G by a ball 111 d. The selected pressure is then output as a second signal pressure P ₂₀ from the output 111 c. The second signal pressure P ₂₀ is input via the opening 101 to the first end chamber 1 of the primary control valve 72 . The line pressure P _L as an output pressure is regulated based on the second signal pressure input to the first end chamber 1 . The explanation of the structure and the function of the primary control valve 72 as a control device is omitted because there is no significant difference to the structure and function described above.

The operation of the hydraulic control system for an automatic transmission will be described with reference to FIGS. 5 and 7. When the oil pump 21 is operated, the hydraulic pressure P _{L is applied} by the oil pump 21 to the inlet opening o of the primary control valve 72 and applied via the opening 102 to the second end chamber n, which is an upper side of the bobbin 72 a, as in the Figure is shown. The bobbin 72 a is pushed down by the hydraulic pressure input to the second end chamber n to the spring 72 b and the bobbin 72 a is held in the position of the left half, as shown in Fig. 5. The bobbin 110 a of the gain control valve 110 is pushed up by the spring 110 b, and the bobbin 110 a is held in the position of the left half in Fig. 5. Therefore, the inlet port c of the boost control valve 110 is closed by the land L ₂ and the line pressure P _L is not input to the boost control valve 110 . The state with a position min is shown in FIG. 7. The reference symbol (P ₂₀ ) on the vertical axis in FIG. 7 shows that the second signal pressure P _{20 is changed} in relation to the change in the first signal pressure P ₁₀ .

In the state when the line pressure linear solenoid valve SLT to the first signal pressure output _10, the first signal pressure P is inputted to the hydraulic chamber A of the gain control valve 110 ₁₀ and the first signal pressure P ₁₀ is input a of Absperrkugelventils 111 in the input 111th At that time, the boost pressure P _G , which is regulated by the line pressure P _L , is not input to the opposite inlet 111 b of the check valve 111 . Therefore, the ball 111 d is pushed to the left in FIG. 5 by the first signal pressure P ₁₀ , which is input into the input 111 a. As a result, the first signal pressure P _{10 is} output as the second signal pressure P ₂₀ from the output 111 c of the shut-off valve 111 . As a result, the second signal pressure P ₂₀ (currently equal to the first signal pressure P ₁₀ ) is input to the first end chamber 1 of the primary control valve 72 through the opening 101 .

If the first signal pressure P _{10 is} increased, the coil body 110 a is gradually pushed down by the first signal pressure P ₁₀ and the second signal pressure P ₂₀ increases gradually. Then the line pressure P _L from the primary control valve 72 also increases. The rate of change of the line pressure P _L with respect to the rate of change of the first signal pressure P ₁₀ , which is the gain G, is shown as the low gain G ₁ in FIG. 7. The low gain G ₁ , which is small in FIG. 7, continues to a change point to be discussed.

When the bobbin 110 a has moved down, by increasing the first signal pressure P ₁₀ so that the upper surface of the web L ₂ passes the upper end of the inlet opening c, the line pressure P _{L is} entered into the inlet opening c of the gain control valve 110 and as Boost pressure P _G output from the outlet port b. The boost pressure P _G is input to the inlet 111 b of the shut-off ball valve 111 . At that time, the line pressure P _L pushes the bobbin 110 a upwards because the pressure area of the lower surface of the web L _{1 of} the bobbin 110 a is larger than the pressure area of the upper surface of the web L ₂ . The force that pushes the bobbin 110 a upwards is calculated by multiplying the area difference between the pressure surface of the lower surface of the web L ₁ and the pressure surface of the upper surface of the web L ₂ , which are subject to the boost pressure P _G. The boost pressure P _G is regulated by the force and the first signal pressure P ₁₀ , which are input into the hydraulic chamber a. The boost pressure P _G from the exit port b is appropriately controlled by setting the difference between the pressure area of the lower surface of the land L ₁ and the pressure area of the upper surface of the land L ₂ . For example, when the difference between the printing areas is small, the boost pressure P _G becomes high with respect to the aforementioned first signal pressure P ₁₀ . Therefore, the gain G can be higher than the high gain G ₂ , which is discussed below.

When the first signal pressure P ₁₀ , which is input into the hydraulic chamber a, is increased, the first signal pressure P ₁₀ , which is input into the inlet 111 a of the shut-off ball valve 111 , and the boost pressure P _G , which is input into the inlet 111 b, increase becomes. Thus, the first signal pressure P _{10 is} output as the second signal pressure P ₂₀ from the output 111 c when the first signal pressure P _{10 is} low because the first signal pressure P _{10 is} higher than the boost pressure P _G and the ball 111 d of the shut-off ball valve 111 after is pushed to the left.

The rate of increase of the boost pressure P _G , which is input into the input 111 b, is greater than the rate of increase of the first signal pressure P ₁₀ , which is input into the input 111 a. The boost pressure P _G is regulated based on the first signal pressure P ₁₀ . The difference between the printing area of the lower surface of the web L ₁ and the printing area of the upper surface of the web L ₂ is set (made) so that it is smaller than the printing area for the first signal pressure P ₁₀ .

Therefore, when the first signal pressure P ₁₀ gradually increases, the boost pressure P _G at a point called the change point shown in FIG. 7 becomes larger than the first signal pressure P ₁₀ . As a result, the ball 111 d of the check valve 111 is pushed to the right, the boost pressure P _{G is} output as the second signal pressure P ₂₀ from the output 111 c, and the second signal pressure P _{20 is} input to the primary regulator valve 72 . The rate of change, which is the gain, of the line pressure P _L from the primary control valve 72 related to the rate of change of the first signal pressure P ₁₀ , which is input into the hydraulic chamber a of the gain control valve 110 , is changed to the high gain G ₂ , which is larger, than the lower gain G ₁ . In this case, the words high and low in the low gain G ₁ and the high gain G _{2 are} relative words and are not used as high and low in the absolute sense.

The high gain G ₂ is continued until the maximum value max of the line pressure P _L corresponding to the maximum value of the first signal pressure P _{10 is} reached. In Fig. 7, the size of the graph shows the gain G and the gain G is the low gain G ₁ when the size is small, and the gain G is the high gain G ₂ when the size is large.

In this exemplary embodiment, the required change range of the line pressure P _L , which lies between min and max in FIG. 7, is reached within the change range of the first signal pressure P ₁₀ , which is output by the line pressure linear solenoid valve SLT.

For example, in the continuously variable transmission 1 shown in FIG. 1, the high-precision control for the line pressure P _L and the high line pressure P _L based on the first signal pressure P ₁₀ are required at different times or conditions. The low gain G ₁ is required for the high accuracy control and the high gain G ₂ is required to achieve the high line pressure P _L. Therefore, it is difficult to achieve both the high-precision control and the high line pressure P _L when the gain G is fixed at a certain value as in the prior art.

That is, when the change range of the first signal pressure P _{10 is} adjusted, in the case where the gain G is set as the low gain G ₁ for achieving the high-precision control, as in Fig. 7 with the alternately long and twice short Dashed line is shown, the required maximum value of the line pressure P _{L is} not reached. In the case where the gain G is set as the high gain G ₂ to obtain the high line pressure P _L , as shown in Fig. 7 with an alternate long and short dash line, the high-precision control for the line pressure is P _L difficult.

Based on the change point within the change range of the first signal pressure P ₁₀ , in the case where the first signal pressure P _{10 is} low and the high-precision control is required, the gain is set as the low gain G ₁ . Then the gain G is set as the high gain G ₂ for the case where the first signal pressure P _{10 is} high and the high line pressure P _{L is} required. Therefore, both the high-precision control for the line pressure P _L and the high line pressure P _{L are achieved} at the appropriate time or under the appropriate conditions.

As a way of achieving the result described, the gain change device, which has the gain control valve 110 and the shut-off ball valve 111 , in the first exemplary embodiment selects the second signal pressure from the first signal pressure P ₁₀ and the boost pressure P _G , the second signal pressure P ₂₀ is sent to the primary control valve 72 is output and the line pressure P _L is regulated based on the second signal pressure P ₂₀ .

An adjustment mechanism and an adjustment type will now be described. In the hydraulic control system shown in FIG. 9, a first adjustment mechanism 120 and a second adjustment mechanism 130 are added to the hydraulic control system shown in FIG. 5.

The first adjusting mechanism 120 is integrally constructed on the lower end portion of the line pressure linear solenoid valve SLT and has an internally threaded portion 120 a, which is formed on the valve body, and an adjusting screw 120 b, which is engaged with the internally threaded portion 120 a. The spring 140 b is arranged between the adjusting screw 120 b and the bobbin 140 a and pressed together. Therefore, the spring load of the spring 140 b to the bobbin 140 a is increased when the screw amount of the adjusting screw 120 b is increased, and is reduced when the screw amount of the adjusting screw 120 b is reduced.

The second adjustment mechanism 130 has the same structure as the first adjustment mechanism 120 . That is, the second adjusting mechanism 130 is integrally constructed on the upper end portion of the boost control valve 110 and has an internally threaded portion 130 a, which is formed on the valve body, and an adjusting screw 130 b, which is engaged with the internally threaded portion 130 a. The spring 110 b is arranged between the adjusting screw 130 b and the bobbin 110 a and compressed. Therefore, the spring load of the spring 110 b to the bobbin 110 a is increased when the screw amount of the adjusting screw 130 b is increased, and it is reduced when the screw amount of the adjusting screw 130 b is reduced.

The line pressure P _L based on a current value I, which is shown in Fig. 10, has the shown spread, which depends on the hydraulic circuit. The maximum and minimum values of the scatter before the setting are shown by the alternately long and twice short dashed line.

In the first embodiment, the boost pressure P _{G is influenced} by the first signal pressure P ₁₀ . Therefore, the boost pressure P _{G is} regulated after the first signal pressure P _{10 has been} regulated.

First, the current value I c to the linear solenoid 140 is of the line pressure linear solenoid valve SLT is applied, a minimum value, and the line pressure P _L, which is relative to the minimum current value, the lowest pressure of the line pressure P _L is measured. When the lowest pressure of the line pressure P _L on the low pressure side is higher than a set point that is a base point, the screw amount of the set screw 120 b of the first set mechanism 120 is increased. Therefore, the spring load of the spring 140 b increases. As a result, the first signal pressure P _{10 is} decreased, and the lowest line pressure P _L matches the set point on the low pressure side. When the lowest pressure of the line pressure P _L on the low pressure side is lower than the set point, which is the base point, the screw amount of the set screw 120 b of the first set mechanism 120 is decreased. Therefore, the spring load of the spring 140 b is reduced. As a result, the first signal pressure P _{10 is} increased and the lowest line pressure P _L matches the set point on the low pressure side.

This setting is essentially the same as in the prior art. Thus, as in the prior art, the line pressure P _{L has} a large spread on the high pressure side at this time.

The invention provides for an adjustment on the high pressure side which is to be carried out by the second adjustment mechanism 130 .

The boost pressure that regulates the line pressure P _L on the high pressure side is regulated. The current value I to the linear solenoid 140 c of the line pressure linear solenoid valve SLT is increased to a maximum value and the line pressure P _L , which is the highest pressure of the line pressure P _L in relation to the maximum current value, is measured. When the highest pressure of the line pressure P _L on the high pressure side is higher than a set point that is a base point, the screw amount of the set screw 130 b of the second adjustment mechanism 130 is increased. Therefore, the spring load of the spring 110 b is increased. As a result, the boost pressure P _{G is} reduced and the highest pressure of the line pressure P _L matches the set point on the high pressure side. When the highest pressure of the line pressure P _L on the high pressure side is lower than the set point, which is the base point, the screw amount of the set screw 130 b of the second set mechanism 130 is decreased. Therefore, the spring load of the spring 110 b is reduced. As a result, the boost pressure P _{G is} increased and the highest pressure of the line pressure P _L matches the set point on the high pressure side.

The spread of the line pressure P _L with respect to the current value I in each hydraulic circuit is reduced by regulating the line pressure P _L at two points which are the set point on the low pressure and the set point on the high pressure side. The scatter according to the settings is shown with an obliquely hatched line section between the alternately long and short dashed lines in FIG. 10. The lowest pressure of the line pressure P _L as the set point on the low pressure side and the highest pressure of the line pressure P _L as the set point on the high pressure side refer to the current value I with high accuracy.

Therefore, there is no need for strength and Consider the durability of the hydraulic circuit and to set the lowest control pressure so that it is high.

The second embodiment will now be described. In the second exemplary embodiment, the first signal pressure P _{10 is} output as the second signal pressure P ₂₀ to the primary control valve 72 when the first signal pressure P _{10 is} low. If the first signal pressure P _{10 is} high, both the first signal pressure P ₁₀ and the boost pressure P _{G are} output as the second signal pressure P ₂₀ to the primary control valve 72 .

The second embodiment is shown in FIG. 6. The elements that have the same structure and the same functions are designated by the same reference numerals or numbers as the previous embodiment. Where the explanations are the same, they are omitted, and only the portions different from the first embodiment will be described.

In FIG. 6, the line pressure linear solenoid valve SLT as the signal pressure output device and the gain control valve are the same as those in Fig. 5. The primary regulator valve 72 A, when the control device, a hydraulic chamber at one end by adding D compared to the control valve 72 of FIG. 5 and 9 extended.

In the second embodiment, a gain changing device has the hydraulic chambers 1, d of the primary control valve 72 A and the gain control valve 110 .

The first signal pressure P ₁₀ output from the line pressure linear solenoid valve SLT is input into the hydraulic chamber 1 of the primary control valve 72 A and gradually pushes the coil body 72 a upwards. Furthermore, the first signal pressure P _{10 is} input to the hydraulic chamber a of the boost control valve 110 and gradually pushes the spool 110 a downward.

In this state, as shown in Fig. 8, the gain G is set as the low gain G ₁ and the low gain G ₁ is maintained until the first signal pressure P _{10 reaches} the change point.

When the first signal pressure P _10, a gradually comes from the line pressure linear solenoid valve SLT, which is input into the hydraulic chamber A of the gain control valve 110 to the spool 110 downward, the boost pressure P _G is output from the output port b and into the hydraulic chamber d of the primary control valve 72 A entered. The coil body 72 a is divided into two sections. One of them is an upper section which is arranged so that the upper section is pushed up by the first signal pressure P ₁₀ . The other is a lower section arranged so that the lower section is pushed up by the boost pressure P _G and pushed down by the first signal pressure P ₁₀ . In the lower section, the printing area for the first signal pressure on the upper surface and the printing area for the boost pressure on the lower surface of the lower section are the same. The upper portion and the lower portion are in contact with each other at the position on the left half side in FIG. 6. When the boost pressure P _{G is} lower than the first signal pressure P ₁₀ , the lower portion is pushed down by the first signal pressure P ₁₀ . Therefore, the boost pressure P _G does not push the upper section of the coil body 72 a of the primary control valve 72 A up over the lower section. Then the upper section is pushed up by the first signal pressure P ₁₀ . When the first signal pressure P ₁₀ rises above the change point, the boost pressure P _{G is} higher than the first signal pressure P ₁₀ . The upper section is then pushed upwards directly by the first signal pressure P ₁₀ and also pushed up by the boost pressure P _G above the lower section. That is, the bobbin 72 a is pushed up by both the first signal pressure P ₁₀ and the boost pressure P _G. Therefore, the first signal pressure P ₁₀ in the second embodiment serves as a second signal pressure P ₂₀ , which pushes the coil body 72 a of the primary control valve 72 A upwards when the first signal pressure P ₁₀ does not increase to the point of change and both the first signal pressure P ₁₀ and the Boost pressure P _G serve as the second signal pressure P ₂₀ when the first signal pressure increases above the change point.

In the first exemplary embodiment, the higher pressure is selected from the first signal pressure P ₁₀ and the boost pressure P _G and serves as the second signal pressure P ₂₀ . But in the second embodiment, as shown in Fig. 8, a pressure shown with a hatched line portion is added to the first signal pressure P ₁₀ by the boost pressure P _G. Therefore, the change from the low gain G ₁ to the high gain G ₂ and the change from the high gain G ₂ to the low gain G _{1 are} carried out smoothly.

FIG. 11 shows the hydraulic control system in which the first adjustment mechanism 120 and the second adjustment mechanism 130 are added to the hydraulic control system shown in FIG. 6.

The hydraulic control system shown in FIG. 11 has the same effect as the hydraulic control system shown in FIG. 9. That is, the line pressure P _L is controlled by regulating the primary control valve 72 A with the first adjustment mechanism 120 of the line pressure linear solenoid valve SLT and the second adjustment mechanism 130 of the boost control valve 110 at the set point on the low pressure side and the set point on the high pressure side. Therefore, the spread of the line pressure P _L , which is based on the current value I in each hydraulic circuit, decreases. The scatter according to the settings is shown with an obliquely hatched line section between the alternately long and short dashed lines in FIG. 10.

To achieve highly accurate line pressure control and high line pressure, a valve control system outputs a first signal pressure P ₁₀ to a primary control valve 72 as a second signal pressure P ₂₀ when the first signal pressure P _{10 is} low. The valve control system outputs a boost pressure P _G to the primary control valve 72 as the second signal pressure P ₂₀ , which is higher than the first signal pressure P ₁₀ when the first signal pressure P _{10 is} high. A change amount of the line pressure from the primary control valve 72 with respect to a change amount of the first signal pressure is a gain. The gain is a low gain that increases the accuracy of line pressure control when the first signal pressure P _{10 is} low, and the gain is a high gain that outputs the high line pressure when the first signal pressure P _{10 is} high.

Claims (12)

1. Hydraulic control system for an automatic transmission, which has the following components:
a signal pressure output device (SLT) which outputs a first signal pressure (P ₁₀ ),
a gain changing device having a gain control valve ( 110 ) that outputs a boost pressure (P _G ) that is controlled based on the first signal pressure (P ₁₀ ), and a selector ( 111 ) that has a second signal pressure (P ₂₀ ) of the selects the first signal pressure (P ₁₀ ) and the boost pressure (P _G ) based on their strength to which the first signal pressure (P ₁₀ ) is input from the signal pressure output device (SLT) and which outputs the second signal pressure (P ₂₀ ) which by the selection device ( 111 ) is selected based on the first signal pressure (P10); and
a control device ( 72 ) into which the second signal pressure (P ₂₀ ) is input from the gain change device and which regulates an output pressure based on the second signal pressure (P ₂₀ ), the gain change device changing a gain that changes a rate of change of the output pressure (P _L ) in relation to the change in the first signal pressure (P ₁₀ ), namely to a low amplification factor (G ₁ ) and a high amplification factor (G ₂ ) within a change range of the first signal pressure (P ₁₀ ). 2. Hydraulic control system for an automatic transmission according to claim 1, characterized in that the selection device ( 111 ) has a shut-off ball ( 111 d) which has the higher pressure of the first signal pressure (P ₁₀ ) and the boost pressure (P _G ) than the second Selects signal pressure (P ₂₀ ) and outputs the second signal pressure (P ₂₀ ) to the control device ( 72 ). 3. Hydraulic control system for an automatic transmission according to claim 2, characterized in that the first signal pressure (P ₁₀ ) is entered into the control device ( 72 ) as a second signal pressure (P ₂₀ ), and the gain factor is changed to the low gain factor (G ₁ ) becomes when the first signal pressure (P ₁₀ ) from the signal pressure output device (SLT) is lower than a predetermined value, and the boost pressure (P _G ), which is higher than the first signal pressure (P ₁₀ ), as a second signal pressure (P ₂₀ ) is input to the control device ( 72 ) and the gain is changed to a high gain (G ₂ ) when the first signal pressure (P ₁₀ ) from the signal pressure output device (SLT) is higher than the predetermined value. 4. Hydraulic control system for an automatic transmission according to claim 1, characterized in that the boost control valve ( 110 ) controls the output pressure (P _L ), which is controlled by the control device ( 72 ), to the boost pressure (P _G ). 5. Hydraulic control system for an automatic transmission according to claim 1, characterized in that the boost control valve ( 110 ) regulates the boost pressure (P _G ) from a low to a high when the first signal pressure (P ₁₀ ) is changed from a low to a high . 6. A hydraulic control system for an automatic transmission according to claim 1, further comprising the following components:
a first adjustment mechanism ( 120 ) that controls the first signal pressure (P ₁₀ ) by adjusting the signal pressure output device (SLT); and
a second adjustment mechanism ( 130 ) that controls the boost pressure (P _G ) by adjusting the boost control valve ( 110 ), the first adjustment mechanism ( 120 ) adjusting the first signal pressure (P ₁₀ ) based on a base point on a low pressure side of the output pressure (P _L ) from the control device ( 72 ), and the second adjustment mechanism ( 130 ) controls the boost pressure (P _G ) based on a base point on a high pressure side of the output pressure (P _L ) from the control device ( 72 ). 7. Hydraulic control system for the automatic transmission according to claim 6, characterized in that the setting for the first signal pressure (P ₁₀ ) by the first adjusting mechanism ( 120 ) earlier than the setting for the boost pressure (P _G ) by the second adjusting mechanism ( 130 ) is carried out. 8. Hydraulic control system for an automatic transmission, which has the following components:
a signal pressure output device (SLT) which outputs a first signal pressure (P ₁₀ );
a gain change device having a gain control valve ( 110 ) that outputs a boost pressure (P _G ) that is regulated based on the first signal pressure (P ₁₀ ) to which the first signal pressure (P ₁₀ ) is input from the signal pressure output device (SLT) and which outputs a second signal pressure based on the first signal pressure (P ₁₀ ); and
a control device ( 72 A) to which the second signal pressure is input from the gain change device and which controls an output pressure (P _L ) based on the second signal pressure, the gain change device changing a gain, which is a rate of change of the output pressure (P _L ) in relation for changing the first signal pressure (P ₁₀ ) to a low amplification factor (G ₁ ) and a high amplification factor (G ₂ ) within a change range of the first signal pressure (P ₁₀ ), the amplification factor changing device representing the first signal pressure (P ₁₀ ) as a second signal pressure outputs to the control device ( 72 A) when the first signal pressure (P ₁₀ ) is lower than a predetermined value, and the amplification factor changing device outputs both the first signal pressure (P ₁₀ ) and the boost pressure (P _G ) as a second signal pressure to the control device ( 72 A) gives when the first signal pressure ck (P ₁₀ ) is higher than the predetermined value. 9. Hydraulic control system for an automatic transmission according to claim 7, characterized in that the boost control valve ( 110 ) controls the output pressure (P _L ) by the control device ( 72 A) to the boost pressure (P _G ). 10. Hydraulic control system for an automatic transmission according to claim 7, characterized in that the boost control valve ( 110 ) regulates the boost pressure (P _G ) from a low to a high when the first signal pressure (P ₁₀ ) is changed from a low to a high . 11. A hydraulic control system for an automatic transmission according to claim 7, further comprising the following components:
a first adjustment mechanism ( 120 ) that controls the first signal pressure (P ₁₀ ) by adjusting the signal pressure output device (SLT); and
a second adjustment mechanism ( 130 ) that regulates the boost pressure (P _G ) by adjusting the boost control valve ( 110 ), the first adjustment mechanism ( 120 ) adjusting the first signal pressure (P ₁₀ ) based on a base point on a low pressure side of the output pressure (P _L ) regulates from the control device ( 72 A); and
wherein the second adjustment mechanism ( 130 ) controls the boost pressure (P _G ) based on a base point on a high pressure side of the output pressure (P _L ) from the control device ( 72 A). 12. Hydraulic control system for the automatic transmission according to claim 11, characterized in that the setting for the first signal pressure (P ₁₀ ) by the first adjusting mechanism ( 120 ) is carried out earlier than the setting for the boost pressure (P _G ) by the second adjusting mechanism ( 130 ).